Abstract: The present invention discloses an equipment for winding medical tubing, employing automated, sequentially-arranged workstations (1, 5, 7) capable of operating simultaneously, comprising one or more conveying units (2), one or more bending units (3) for arranging medical tubing (10) in a U shape, one or more loading units (4), one or more winding stations (5) for winding medical tubing (10), one or more unloading units (6) and, optionally, one or more packaging units (7).

Abstract: The present invention discloses an equipment for winding medical tubing, employing automated, sequentially-arranged workstations (1, 5, 7) capable of operating simultaneously, comprising one or more conveying units (2), one or more bending units (3) for arranging medical tubing (10) in a U shape, one or more loading units (4), one or more winding stations (5) for winding medical tubing (10), one or more unloading units (6) and, optionally, one or more packaging units (7).

Abstract: The present disclosure relates to systems, apparatuses, and methods for assembling cartridges for aerosol delivery devices. A system may include assembly cells each including an assembly track and assembly carriages that ride thereon and which engage components of partially-assembled cartridges. A transfer apparatus may transfer partially-assembled cartridges between the assembly cells. In another example system, cartridges may be assembled on platforms on a rotary track. The platforms may include assembly grippers with sequentially-opening clamps configured to receive the components of the partially-assembled cartridges. Related methods are also provided.

Abstract: The present disclosure relates to systems, apparatuses, and methods for assembling cartridges for aerosol delivery devices. A system may include assembly cells each including an assembly track and assembly carriages that ride thereon and which engage components of partially-assembled cartridges. A transfer apparatus may transfer partially-assembled cartridges between the assembly cells. In another example system, cartridges may be assembled on platforms on a rotary track. The platforms may include assembly grippers with sequentially-opening clamps configured to receive the components of the partially-assembled cartridges. Related methods are also provided.

Abstract: The present disclosure relates to systems, apparatuses, and methods for assembling cartridges for aerosol delivery devices. A system may include assembly cells each including an assembly track and assembly carriages that ride thereon and which engage components of partially-assembled cartridges. A transfer apparatus may transfer partially-assembled cartridges between the assembly cells. In another example system, cartridges may be assembled on platforms on a rotary track. The platforms may include assembly grippers with sequentially-opening clamps configured to receive the components of the partially-assembled cartridges. Related methods are also provided.

Abstract: The present disclosure relates to systems, apparatuses, and methods for assembling cartridges for aerosol delivery devices. A system may include assembly cells each including an assembly track and assembly carriages that ride thereon and which engage components of partially-assembled cartridges. A transfer apparatus may transfer partially-assembled cartridges between the assembly cells. In another example system, cartridges may be assembled on platforms on a rotary track. The platforms may include assembly grippers with sequentially-opening clamps configured to receive the components of the partially-assembled cartridges. Related methods are also provided.

Abstract: The present disclosure relates to systems, apparatuses, and methods for assembling cartridges for aerosol delivery devices. A system may include assembly cells each including an assembly track and assembly carriages that ride thereon and which engage components of partially-assembled cartridges. A transfer apparatus may transfer partially-assembled cartridges between the assembly cells. In another example system, cartridges may be assembled on platforms on a rotary track. The platforms may include assembly grippers with sequentially-opening clamps configured to receive the components of the partially-assembled cartridges. Related methods are also provided.

Abstract: A method of turning a medical device, having a magnetically responsive element associated with its distal end, at an operating point within an operating region inside a patient's body from an initial direction to a desired final direction, through the movement of at least one external source magnet. The at least one external source magnet is moved in such a way as to change the direction of the distal end of the magnetic medical device from the initial direction to the desired final direction without substantial deviation from the plane containing the initial direction and the desired final direction.

Abstract: An apparatus and method for interventional navigation within a subject's body is provided in which a medical device having at least one electrostrictive element is adapted to cause the distal end of the medical device to bend in a given direction for improving navigation. The medical device may further comprise at least one magnetically responsive element on the distal end, which may be oriented in the approximate direction of a magnetic field that is applied to the subjects body. At least one method for navigating a medical device though a subject's body is provided, by changing the direction of an applied magnetic field to align a magnetically responsive element on the distal end for orienting the distal end, and by applying a voltage to at least one electrostrictive element disposed in the distal portion of the device for causing the distal end to change orientation from that achieved by application of the magnetic field alone.

Abstract: A method of navigating a magnet-tipped distal end of an elongate medical device through the body includes providing an image display of the part of the body through which the medical device is being navigated and using the display to input the desired path of the medical device by identifying points on the desired path on the display. The magnetic field needed to orient the end of the medical device in the direction of the desired path as indicated on the display is then determined. In one embodiment where only points on the desired path are identified, the field direction is the direction indicated by the points on the desired path.

Abstract: A system for remotely navigating a medical device in an operating region in a subject. An inertial sensing device in the medical device distal end has one or more inertial sensors that provide information for locating the medical device. A controller is operable to control movement of the medical device based on the locating information to navigate the device distal end to a target point.

Abstract: A medical catheter or guide wire comprising one or a plurality of combinations of magnetically permanent or permeable elements attached to an elongated structural element, the medical device being controllably bendable at the element combination(s) upon application of a magnetic field generally in the direction of the local element long axis.

Abstract: A method of and system for navigating a medical device in a subject. The device has a magnet in a tip of the device and is navigable in the subject using source magnets positioned outside the subject. A source magnet magnetic field is used to navigate the device tip to a point in the subject. A boost magnetic moment is created by boost coils and is added to a permanent tip magnet moment to increase the torque applied by the externally generated magnetic field to the device tip. At least one boost magnet is used to apply the boost magnetic field. This method also makes it possible to design magnetic navigation systems with reduced size and cost.

Abstract: A method of turning a medical device, having a magnetically responsive element associated with its distal end, at an operating point within an operating region inside a patient's body from an initial direction to a desired final direction, through the movement of at least one external source magnet. The at least one external source magnet is moved in such a way as to change the direction of the distal end of the magnetic medical device from the initial direction to the desired final direction without substantial deviation from the plane containing the initial direction and the desired final direction.

Abstract: A method of operating a remote medical navigation system using ultrasound, employs ultrasound imaging from a medical device to supplement or to replace conventional x-ray imaging of the operating region during navigation.

Abstract: An apparatus and method for locating a magnetic implant in a surgical application using the field of a source magnet for the implant guiding field. The source magnet is an electromagnet having a separate calibrated magnetic field component in addition to the guiding field, so that both the magnitude and orientation of the magnetic field as a function of position around the magnet are known. A magnetic implant is provided with a sensor, such as a three-axis Hall effect sensor, to provide an indication of the magnitude and orientation of an applied magnetic field when the implant is surgically implanted in a patient. After implantation, the source magnet is energized with a current having a modulated component.

Abstract: A magnetically navigable catheter or guide wire having a proximal and a distal end, and a magnetically responsive structure that surrounds at least a portion of the catheter or guide wire at the distal end, wherein the magnetically responsive structure is comprised of a flexible magnetically responsive material.

Abstract: A method for controlling a remote navigation system to navigate a medical device in an operating region in a subject is provided, comprising operating the remote navigation system to bring a sensor carried on a medical device successively into a plurality of locations in a predetermined pattern, and using the sensor to sense a physiological property of the subject in each location. At least once thereafter, the method operates the remote navigation system to bring a sensor carried on a medical device successively into a series of locations in a predetermined pattern relative to at least one location selected from the predetermined pattern in the immediately preceding step based upon the sensed physiological property value, and uses the sensor to sense the physiological property in each location.

Abstract: A fishing reel includes a spool disk, a handle disk mounted coaxially and in juxtaposition with the spool disk, a winding handle or crank affixed to the handle disk, and a brake mechanism, including an actuator incorporated in the handle, for applying a drag braking torque between the spool disk and the handle disk. The braking torque is controllable by a user by squeezing the handle while holding the handle for cranking. Accordingly, the user does not have to let go of the winding handle in order to apply or vary the drag.

Abstract: A system for magnetically imaging an operating region in a subject and magnetically navigating a medical device within the operating region includes a first magnet for applying a static magnetic field to the operating region of sufficient strength for magnetically imaging the operating region and sufficiently strong to permit a medical device to be oriented in the operating region by creating a magnetic moment at the distal end of the medical device, and a second magnet for applying a static magnetic field to the operating region of sufficient strength for magnetically imaging the operating region and sufficiently strong to permit a medical device to be oriented in the operating region by creating a magnetic moment at the distal end of the medical device. In an alternate construction, the system includes a first magnet that is movable between a first position to apply a first static magnetic field to the operating region and a second position to apply a second static magnetic field to the operating region.